A novel waterborne polyurethane with biodegradability and high flexibility for 3D printing

Feng, Zhipeng; Wang, Di; Zheng, Yudong; Zhao, Liang; Xu, Tao; Guo, Zhimeng; Hussain, Mubashir; Zeng, Jinshi; Lou, Lingyun; Sun, Yi; Jiang, Haiyue

doi:10.1088/1758-5090/ab7de0

Cited by 38 publications

(31 citation statements)

References 52 publications

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“…The use of WBPUUs with different compositions as printing inks for DIW 3D printing has been reported in the literature in the last years, mostly focused on biomedical applications [9,11] In a recent work, Feng et al synthesized a biodegradable WBPUU modified with an amino acid, presenting good flexibility and biocompatibility with a potential application in tissue engineering via 3D printing [12]. In another study, Hsieh et al examined the viability of a thermoresponsive WBPUU that formed a gel near 37 • C without any cross-linker.…”

Section: Introductionmentioning

confidence: 99%

Design of a Waterborne Polyurethane–Urea Ink for Direct Ink Writing 3D Printing

Vadillo

Larraza²,

Calvo‐Correas³

et al. 2021

Materials

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In this work, polycaprolactone–polyethylene glycol (PCL–PEG) based waterborne polyurethane–urea (WBPUU) inks have been developed for an extrusion-based 3D printing technology. The WBPUU, synthesized from an optimized ratio of hydrophobic polycaprolactone diol and hydrophilic polyethylene glycol (0.2:0.8) in the soft segment, is able to form a physical gel at low solid contents. WBPUU inks with different solid contents have been synthesized. The rheology of the prepared systems was studied and the WBPUUs were subsequently used in the printing of different pieces to demonstrate the relationship between their rheological properties and their printing viability, establishing an optimal window of compositions for the developed WBPUU based inks. The results showed that the increase in solid content results in more structured inks, presenting a higher storage modulus as well as lower tan δ values, allowing for the improvement of the ink’s shape fidelity. However, an increase in solid content also leads to an increase in the yield point and viscosity, leading to printability limitations. From among all printable systems, the WBPUU with a solid content of 32 wt% is proposed to be the more suitable ink for a successful printing performance, presenting both adequate printability and good shape fidelity, which leads to the realization of a recognizable and accurate 3D construct and an understanding of its relationship with rheological parameters.

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Section: Introductionmentioning

confidence: 99%

Design of a Waterborne Polyurethane–Urea Ink for Direct Ink Writing 3D Printing

Vadillo

Larraza²,

Calvo‐Correas³

et al. 2021

Materials

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“…Ideally, the degradation rate of scaffolds matches the production rate of ECM, whilst the degradation products have no side effects on the host (Sabir et al, 2009). For example, the mass loss of a waterborne polyurethane scaffold reached 35.62% after 90 days of degradation, while the fluorescence image showed that after 7 days of incubation, rabbit chondrocytes covered all waterborne polyurethane scaffolds (Feng et al, 2020). (5) Surface characteristics: The interface between the scaffold and the tissue to be repaired is critical to the success of a scaffold transplantation, with numerous reactions and interactions taking place.…”

Section: Property Requirements Of Bioinks/scaffoldsmentioning

confidence: 99%

Bioink Formulations for Bone Tissue Regeneration

Guo

Zhang

2021

Front. Bioeng. Biotechnol.

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Unlike the conventional techniques used to construct a tissue scaffolding, three-dimensional (3D) bioprinting technology enables fabrication of a porous structure with complex and diverse geometries, which facilitate evenly distributed cells and orderly release of signal factors. To date, a range of cell-laden materials, such as natural or synthetic polymers, have been deployed by the 3D bioprinting technique to construct the scaffolding systems and regenerate substitutes for the natural extracellular matrix (ECM). Four-dimensional (4D) bioprinting technology has attracted much attention lately because it aims to accommodate the dynamic structural and functional transformations of scaffolds. However, there remain challenges to meet the technical requirements in terms of suitable processability of the bioink formulations, desired mechanical properties of the hydrogel implants, and cell-guided functionality of the biomaterials. Recent bioprinting techniques are reviewed in this article, discussing strategies for hydrogel-based bioinks to mimic native bone tissue-like extracellular matrix environment, including properties of bioink formulations required for bioprinting, structure requirements, and preparation of tough hydrogel scaffolds. Stimulus mechanisms that are commonly used to trigger the dynamic structural and functional transformations of the scaffold are analyzed. At the end, we highlighted the current challenges and possible future avenues of smart hydrogel-based bioink/scaffolds for bone tissue regeneration.

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“…It has been widely applied in such fields as marine anti-fouling coatings and metal coatings, radioactive materials, drug-delivery systems, biomedical engineering scaffolds, implantable bioelectronics and so on. [10][11][12] Furthermore, biodegradable materials are a type of materials, which are friendly to the environment and have shown good effects on maintaining a controlled-release performance. [13][14][15][16] For example, fertilizers coated with biodegradable materials can improve the nutrient absorption and avoid the nutrient diversion loss during the process of degradation.…”

Section: Introductionmentioning

confidence: 99%

Preparation and Characterization of Glucose and Sulfamate Double‐Modified Biodegradable Waterborne Polyurethane

Yang

et al. 2021

ChemistrySelect

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A kind of glucose and sulfamate double-modified waterborne polyurethane (WPU) was synthesized by using glucose (GLC) and N-[(2-amionoethyl)-amino] ethane sulphonated sodium (AAS) as internal crosslinking agent, polycaprolactone glycol (PCL) as soft segment, 2,2-bis(hydroxymethyl) propionic acid (DMPA) and N-[(2-amionoethyl)-amino] ethane sulphonated sodium (AAS) as hydrophilic monomers. The influences of AAS and GLC content on the WPU structure and properties were analyzed and characterized by high speed of centrifugation, particle size examination, ATR-FTIR, TEM, DMA, TGA, SEM, tensile tests, contact angle, water uptake and degradation measurements. The test results indicated that the modified biodegradable WPU had great comprehensive properties. Compared with the unmodified polyurethane, the prepared cross-linked WPU had a good stability (over 6 months), outstanding mechanical strength (51.55 MPa for WPU4 films) and biodegradability (the weight loss in soil and PBS/lipase reached 25.2 % and 11.8 % for 6 weeks), which made them appropriate supplements for the traditional waterborne polyurethanes in the future.

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A novel waterborne polyurethane with biodegradability and high flexibility for 3D printing

Cited by 38 publications

References 52 publications

Design of a Waterborne Polyurethane–Urea Ink for Direct Ink Writing 3D Printing

Design of a Waterborne Polyurethane–Urea Ink for Direct Ink Writing 3D Printing

Bioink Formulations for Bone Tissue Regeneration

Preparation and Characterization of Glucose and Sulfamate Double‐Modified Biodegradable Waterborne Polyurethane

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